Morse Theoretic Aspects of p-Laplacian Type Operators Kanishka Perera Ravi P. Agarwal Donal O'Regan American Mathematical Society Morse Theoretic Aspects of p-Laplacian Type Operators Mathematical Surveys and Monographs Volume 161 Morse Theoretic Aspects of p-Laplacian Type Operators Kanishka Perera Ravi P. Agarwal Donal O'Regan American Mathematical Society Providence, Rhode Island EDITORIAL COMMITTEE Jerry L. Bona Michael G. Eastwood Ralph L. Cohen, Chair J. T. Stafford Benjamin Sudakov 2000 Mathematics Subject Classification. Primary 58E05, 47305, 47310, 35360. For additional information and updates on this book, visit www.arns.org/bookpages/surv-161 Library of Congress Cataloging-in-Publication Data Perera, Kanishka, 1969- Morse theoretic aspects of p-Laplacian type operators / Kanishka Perera, Ravi Agarwal, Donal O'Regan. p. cm. (Mathematical surveys and monographs v. 161) Includes bibliographical references ISBN 978-0-8218-4968-2 (alk. paper) 1. Morse theory. 2. Laplacian operator. 3. Critical point theory (Mathematical analysis) I. Agarwal, Ravi, 1947- It. O'Regan, Donal. III. Title QA614.7.P47 2010 515'.3533-dc22 2009050663 Copying and reprinting. Individual readers of this publication, and nonprofit libraries acting for them, are permitted to make fair use of the material, such as to copy a chapter for use in teaching or research. Permission is granted to quote brief passages from this publication in reviews, provided the customary acknowledgment of the source is given. Republication, systematic copying, or multiple reproduction of any material in this publication is permitted only under license from the American Mathematical Society. Requests for such permission should be addressed to the Acquisitions Department, American Mathematical Society, 201 Charles Street, Providence, Rhode Island 02904-2294 USA. Requests can also be made by e-mail to reprint-permission0ams.org. © 2010 by the American Mathematical Society. All rights reserved. The American Mathematical Society retains all rights except those granted to the United States Government. Printed in the United States of America. ® The paper used in this book is acid-free and falls within the guidelines established to ensure permanence and durability. Visit the AMS home page at http://ww.ans.org/ 10987654321 151413121110 Contents Preface vii An Overview ix Chapter 0. Morse Theory and Variational Problems 0.1. Compactness Conditions 0.2. Deformation Lemmas 0.3. Critical Groups 0.4. Minimax Principle 0.5. Linking 0.6. Local Linking 0.7. p-Laplacian Chapter 1. Abstract Formulation and Examples 1.1. p-Laplacian Problems 1.2. AP Laplacian Problems 1.3. Problems in Weighted Sobolev Spaces 1.4. q-Kirchhoff Problems 1.5. Dynamic Equations on Time Scales 1.6. Other Boundary Conditions 1.7. p-Biharmonic Problems 1.8. Systems of Equations Chapter 2. Background Material 2.1. Homotopy 2.2. Direct Limits 2.3. Alexander-Spanier Cohomology Theory 2.4. Principal 712-Bundles 2.5. Cohomological Index Chapter 3. Critical Point Theory 3.1. Compactness Conditions 3.2. Deformation Lemmas 3.3. Minimax Principle 3.4. Critical Groups 3.5. Minimizers and Maximizers 3.6. Homotopical Linking 3.7. Cohomological Linking V CONTENTS vi 3.8. Nontrivial Critical Points 3.9. Mountain Pass Points 3.10. Three Critical Points Theorem 3.11. Cohomological Local Splitting 3.12. Even Functionals and Multiplicity 3.13. Pseudo-Index 3.14. Functionals on Finsler Manifolds Chapter 4. p-Linear Eigenvalue Problems 4.1. Variational Setting 4.2. Minimax Eigenvalues 4.3. Nontrivial Critical Groups Chapter 5. Existence Theory 5.1. p-Sublinear Case 5.2. Asymptotically p-Linear Case 5.3. p-Superlinear Case Chapter 6. Monotonicity and Uniqueness Chapter 7. Nontrivial Solutions and Multiplicity 89 7.1. Mountain Pass Solutions 89 7.2. Solutions via a Cohomological Local Splitting 90 7.3. Nonlinearities that Cross an Eigenvalue 91 7.4. Odd Nonlinearities 93 Chapter 8. Jumping Nonlinearities and the Dancer-Fucik Spectrum 97 8.1. Variational Setting 99 8.2. A Family of Curves in the Spectrum 100 8.3. Homotopy Invariance of Critical Groups 102 8.4. Perturbations and Solvability 105 Chapter 9. Indefinite Eigenvalue Problems 109 9.1. Positive Eigenvalues 109 9.2. Negative Eigenvalues 111 9.3. General Case 112 9.4. Critical Groups of Perturbed Problems 113 Chapter 10. Anisotropic Systems 117 10.1. Eigenvalue Problems 119 10.2. Critical Groups of Perturbed Systems 125 10.3. Classification of Systems 128 Bibliography 135 Preface The p-Laplacian operator Apu = div (IVulr-2 Vu), PC (1, GO) arises in non-Newtonian fluid flows, turbulent filtration in porous media, plasticity theory, rheology, glaciology, and in many other application areas; see, e.g., Esteban and Vazquez [48] and Padial, Takae, and Tello [90]. Prob- lems involving the p-Laplacian have been studied extensively in the literature during the last fifty years. However, only a few papers have used Morse the- oretic methods to study such problems; see, e.g., Vannella [130], Cingolani and Vannella [29, 31], Dancer and Perera [40], Liu and Su [74], Jiu and Su [58], Perera [98, 99, 100], Bartsch and Liu [15], Jiang [57], Liu and Li [75], Ayoujil and El Amrouss [10, 11, 12), Cingolani and Degiovanni [30], Guo and Liu [55], Liu and Liu [73], Degiovanni and Lancelotti [43, 44], Liu and Geng [70], Tanaka [129], and Fang and Liu [50]. The purpose of this monograph is to fill this gap in the literature by presenting a Morse theo- retic study of a very general class of homogeneous operators that includes the p-Laplacian as a special case. Infinite dimensional Morse theory has been used extensively in the lit- erature to study semilinear problems (see, e.g., Chang [28] or Mawhin and Willem [81]). In this theory the behavior of a Cl-functional defined on a Banach space near one of its isolated critical points is described by its critical groups, and there are standard tools for computing these groups for the variational functional associated with a semilinear problem. They include the Morse and splitting lemmas, the shifting theorem, and various linking and local linking theorems based on eigenspaces that give critical points with nontrivial critical groups. Unfortunately, none of them apply to quasilinear problems where the Euler functional is no longer defined on a Hilbert space or is C2 and there are no eigenspaces to work with. We will systematically develop alternative tools, such as nonlinear linking and local linking theories, in order to effectively apply Morse theory to such problems. A complete description of the spectrum of a quasilinear operator such as the p-Laplacian is in general not available. Unbounded sequences of eigen- values can be constructed using various minimax schemes, but it is generally not known whether they give a full list, and it is often unclear whether dif- ferent schemes give the same eigenvalues. The standard eigenvalue sequence based on the Krasnoselskii genus is not useful for obtaining nontrivial critical vii viii PREFACE groups or for constructing linking sets or local linkings. We will work with a new sequence of eigenvalues introduced by the first author in [98] that uses the 7Z2-cohomological index of Fadell and Rabinowitz. The necessary background material on algebraic topology and the cohomological index will be given in order to make the text as self-contained as possible. One of the main points that we would like to make here is that, contrary to the prevailing sentiment in the literature, the lack of a complete list of eigenvalues is not a serious obstacle to effectively applying critical point the- ory. Indeed, our sequence of eigenvalues is sufficient to adapt many of the standard variational methods for solving semilinear problems to the quasi- linear case. In particular, we will obtain nontrivial critical groups and use the stability and piercing properties of the cohomological index to construct new linking sets that are readily applicable to quasilinear problems. Of course, such constructions cannot be based on linear subspaces since we no longer have eigenspaces. We will instead use nonlinear splittings based on certain sub- and superlevel sets whose cohomological indices can be precisely calculated. We will also introduce a new notion of local linking based on these splittings. We will describe the general setting and give some examples in Chap- ter 1, but first we give an overview of the theory developed here and a preliminary survey chapter on Morse theoretic methods used in variational problems in order to set up the history and context. An Overview Let D be a C1-functional defined on a real Banach space W and satisfying the (PS) condition. In Morse theory the local behavior of 4' near an isolated critical point u is described by the sequence of critical groups (1) Cq ($, u) = Hq(,D` n U, $` n U\ {u}), q >, 0 where c = 'F(u) is the corresponding critical value, 4'` is the sublevel set {u e W : f(u) 5 c}, U is a neighborhood of u containing no other critical points, and H denotes cohomology. They are independent of U by the excision property. When the critical values are bounded from below, the global behavior of 4' can be described by the critical groups at infinity Cq(1D, co) = Hq(W,1"), q ? 0 where a is less than all critical values. They are independent of a by the sec- ond deformation lemma and the homotopy invariance of cohomology groups. When 4' has only a finite number of critical points u1,... , Uk, their critical groups are related to those at infinity by k rank Cq(4',uj) >, rank Cq(4',co) Vq a=1 (see Proposition 3.16). Thus, if C"(4', oo) # 0, then 4' has a critical point u with Cq(4',u) # 0. If zero is the only critical point of (F and 4) (0) = 0, then taking U = W in (1), and noting that (F° is a deformation retract of W and 4'°\ {0} deformation retracts to (DI by the second deformation lemma, gives Cq(4',0)=Hq(4'°,4'°\{0}) Hq(W,,D°\{0}) z Hq(W,,Da) = Cq(4', ao) Vq. Thus, if Cq(4', 0) 4 Cq((F, co) for some q, then D has a critical point u # 0. Such ideas have been used extensively in the literature to obtain multiple nontrivial solutions of semilinear elliptic boundary value problems (see, e.g., Mawhin and Willem [81], Chang [28], Bartsch and Li [14], and their refer- ences). Now consider the eigenvalue problem OP u = Alujp-2 u in S2 i u=0 onOQ ix